DE2054218A1 - Controllable pressure control valve designed as an overflow valve - Google Patents

Description

Dr. Ing. Hans A. Trossen 8103 Tint er engs tr ing en

Controllable pressure control valve designed as an overflow valve.

The present invention relates to an overflow valve designed as a j formed, controllable pressure control valve to keep a constant continuously controllable druokes in a system, in particular in a fluid system, with at least one acted upon during operation Drain connection with controlled static medium pressure and a Overflow parts formed valve passage for discharging the excess medium.

Conventionally, controllable pressure regulating valves are by spring or Grewiohts arrangements controlled. This is relatively complicated ornamental weight and lever arrangements or requires special springs on the valve plate, the division of the valve to others being constant Preselected discharge pressure to be held, cumbersome changes which makes spring or thread arrangements necessary and cannot be made continuously adjustable in a simple manner.

In order to remedy these disadvantages, the present invention is drawn up characterized in that one or more electro-magnets and one or several springs are arranged in the valve to act on the valve

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body to exert a position-independent force corresponding to the coil current.

Embodiments of the subject matter of the invention are attached below explained with reference to figures; Ss show:

1 shows a longitudinal section of a spring-loaded and magnetically loaded, controllable pressure holding valve in the open position

Fig. 2 is a force-displacement diagram that acts on the valve body of the Druok- ^ holding valve according to FIG. 1 acting forces, "a" the

Characteristic of a linear and "b" of a progressive one Spring represents

3 shows the dependence of the pressure difference on the basis of a diagram

A ρ of a spring-loaded and magnetically loaded valve according to Fig. from the coil current I, with two different spring preloads

4 shows a longitudinal section of a controllable pressure holding valve of a different design, in which the spring return force and the magnetic force are rectified

5 shows a force-displacement diagram for spring restoring and magnetic force of the valve of FIG. 4 and its resultant, at different coil currents

6 shows the dependence of the pressure difference on the basis of a diagram Δ ρ of a valve according to FIG. 4 from the coil current I for different biases of the spring

7 shows a force-displacement diagram for spring and magnetic force of a

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Pressure holding valve in which the spring is between the valve disc and solenoid in the gap L (Fig. 4) is arranged

8 shows the dependence of the differential pressure on the basis of a diagram 4 ρ of a valve according to the characteristics of Fig. 7, from the coil current I, with different spring preloads

9 shows a controllable pressure holding valve, with an iron core of a Pot magnet in the magnet cavity is designed as a sleeve for the valve body, which by means of membranes from the flowing through Medium is liquid-free.

In the pressure holding valve according to FIG. 1, an inflow line 1 opens into a valve housing 3 made of non-magnetic material. In this there is a pot magnet with a bobbin 5, a pot 7 and an iron core 9. This pot magnet is on the front side with a plate 10 made of non-magnetic material. The iron core 9 has at one end a threaded bolt 12 which through the pot 7 and the rear wall of the valve housing 3 protrudes. The other end of the iron core 9, which protrudes from the plate 10, is larger in diameter. By screwing on a nut 13 the thread 12 is the plate 10, the Verfctiltopf 7 and the bobbin 5 held in the valve housing 3. At the widened end of the iron core 9, a threaded bushing 15 is embedded on the a metal membrane 19 is screwed tight by means of a screw 17. Threaded bushing 15 and screw 17 are made of non-magnetic material. The metal membrane 19 is connected on its periphery to a valve disk 21, e.g. spot-welded. This valve disk 21 is curved and its distance from the screw 17 so large that in the lifting

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area of the valve no obstruction of the valve by the screw 17 can be done. To the pot 7, a compression spring 23 is arranged, which the valve disk 21 with a guide groove 22 as Spring plate is used. On the valve plate 21, a sealing washer 25 is arranged coaxially to the inflow line 1, the size of which on the The size of the opening of the inflow line 1 is matched. The drainage of the excess medium from the valve housing 3 takes place duroh an opening 31. In the inflow line 1, before the branching off of a line 29, in which there is controlled pressure, there is an orifice or nozzle 27 arranged.

Suppose a liquid flows at such a speed duroh the diaphragm or nozzle 27, that the desired pressure occurs in the discharge line 29, or the intended pressure Flows amount of liquid, the valve opening 28 is through the Sealing washer 25 resting on the end of the line is closed. Several lines 29 can also be provided. Increases the inflowing amount of liquid and with it the inflow velocity, the liquid pressure on the valve disk 21 is increased. The system is now no longer in equilibrium. Assuming that the valve disk 21 is against the spring force of the Spring 23 is pushed away from the end of the line until the force from the newly set pressure and the restoring force of spring 23 are in equilibrium keep. In this open valve position, there would be an overpressure in the inflow line 1 compared to the original pressure to rule. The pressure in the inflow line 1 would therefore be greater than the initial pressure by a value corresponding to the valve opening. In order to restore the original pressure in the inflow line 1

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are sufficient, the valve has to be opened noon, which is done by a force counter to the spring return force. The opening takes place until the resulting restoring force and the pressure-related force of the pressure, which has fallen to the initial value due to the further opening of the valve, maintain equilibrium. This force, which supports the fluid pressure and opens the valve, is caused by the pot magnet. One pole is the pot 7, while the other pole is formed by the iron core 9. The magnetic field lines therefore run from the. Sisenkern 9, the H-PoI, over the air gap L * to the valve disk 21 and from this g through the air gap L to the opposite pole S, the pot 7 which progressively decreases or increases with increasing or decreasing air gap size L. The direction of the bottom closing force is said to be positive. Then there is the one in Jig for this magnetic force. 2 illustrated distance dependency K ^ »f (L). Depending on the selection of the coil current I χ, this force-displacement function can be shifted to saturation with respect to the abscissa, i.e. in the direction of the force axis K (ordinate), with the characteristic of this function remaining almost the same in a limited range. The each restoring force K, which runs in the opposite direction to the magnetic force K, is also shown in FIG. 2 as a function of the distance L. From the superimposed punctures according to Flg. 2 shows that in the area I * the resulting force R from the spring force X ^ and magnetic force K, is almost constant, since in this area of the valve body stroke the magnetic force K ^ and the spring force Kj are practically directly proportional to the stroke · Change a L · Di · Curve "a" shows the characteristic of a linear one, curve "b" shows the one

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a progressive spring. For larger areas AL, the spring characteristic Ky must be equally curved, i.e. progressive like the magnetoharacteristic K ^, for better agreement, ie better keeping R constant. The resultant R therefore corresponds to the force that a desired pressure exerts on the valve disk 21. It can be changed according to the desired pressure by the coil current (blade parameter I). A certain valve position with the coil current kept constant does not correspond to a certain differential pressure Ap, but to a certain inflow quantity or inflow speed. The differential pressure Ap thus has a constant value for every valve position in the interval a L. The diagram according to FIG. 3 shows the relationship between the differential pressure AP and the coil current I for two different spring preloads of the compression spring 3 (FIG. 1). The straight line "1" applies to a stronger, «2« to a weaker spring preload. P _{1 is} the controlled pressure and P _{0 is} the ambient pressure. If a strong spring preload is set, the coil current I ₁ must be for an equally large controlled pressure p, and with the same ambient pressure p. be selected larger (point A) than the coil current I ₂ with a weaker spring preload (point B).

A valve with the arrangement according to FIG. 4 can achieve the smooth effect exhibit. Sin made of non-magnetic material, e.g. plastic, existing supply pipe 32 protrudes duroh the inner cavity of a pot magnet with a bobbin 5 and a pot 7 Feed pipe 32 is a pin pipe 33 serving as a magnet core arranged between the bobbin 5 and the supply pipe 32. This iron pipe 33 protrudes beyond the end face of the pot magnet

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attached plate 10 made of non-magnetic material. The feed pipe 32 protrudes over the Ilsen pipe 33. Above the end face of the pot magnet is mounted as a valve housing a bushing 34 made of nichtmagnetisehern material, in addition to the mouth of the feed pipe 32 a valve disk 35 and behind it, a compression spring 36 UmSChIIeSSt ₁ The end wall of the bushing 34 is of the spring 36 as a support.

The valve disc 35 which is centrally invaginated, forms with its recessed edge of the spring plate of the spring 36. It can taking into λ utilization of the spring are moved axially in the bush 34 36th The valve plate 35 is with a coaxially attached seal 37 opposite the mouth of the supply _{pipe 32. The spring 36 presses the valve plate 35 and thus the seal 37 with the force K n} , looking at the mouth of the pipe 32. The through the pipe 32 in the

_The flowing medium can escape through a pot magnet / pot magnet Aind valve plate 35 mounted in the sleeve 34 over a port 38, while in a drain line 39 the medium flows off with controlled pressure. Here, as shown in FIG. 1, the magnet causes a force K ^, rectified with the bottom closing force, on the valve disk 35. If the magnetic force increases as the distance L between the valve disk 35 and the magnet decreases, the spring restoring force K ™ falls. If the two characteristics are superimposed, then in a certain distance range & L a position-independent, constant positive force R, that is to say acting in the direction of the bottom, is evident. 1 ": strong," 2 ^M : medium, "3 ^M : no preload) the valve opens at the desired differential pressure. If the coil current I- is set

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and spring preload zero ("3") a differential pressure νοηΔΡ-, ein, βο a smaller coil current I _{2 is} required in order to obtain _{the same differential pressure 6P 1} with a medium spring preload ("2").

It is also entirely possible to design the valve according to FIG. 4 in such a way that the spring and the pot magnet are attached to the same side of the valve disk. This arrangement works basically the same as that according to FIG. 1, but the forces acting on the valve plate have opposite signs and they become smaller as the valve opens, i.e. the spring is pretensioned when the valve is closed and the resultant, e.g. R _4, is constant in the range ^ L, in order to ensure the independence of the pressure τοη the inflow amount in the medium upstream of the valve body. This arrangement results in characteristics according to FIGS. 7 and 8, that is to say of a valve which produces the same effect as the variants described above. In Flg. 8 the straight line "1" applies with, the straight line ⁿ 2 "without bias.

Another constructive variant is shown in FIG. 9. On one with one Cover plate 53 provided with line 52, a pot 54 of a pot magnet is fastened coaxially with the line 52. The pot 54 is like this designed that it is protected by a plastic sheath 55 Bobbin 56 carries. The inside of the pot is dimensioned so that between the bobbin 56 and the cover plate 53, as well as between the bobbin 56 and the outer wall of the pot 54 Cavity 64 is created. A valve body 58 also serves to guide and support a compression spring 60.

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A bolt 59 is provided in the valve body 58 for fastening a membrane 70 at the bottom. A sleeve 71 made of non-magnetic material, which is fastened to the bottom of the pot 54, serves as an external receptacle for the membrane 70 and at the same time supports the compression spring 60. The sleeve 71 has an opening 61 through which the bolt 59, depending on the movement of the valve body 58, can exit. The middle part of the pot 54 is designed as a sleeve 57 protruding into the magnet cavity, in which the valve body 58 is moved like a piston. The pot 54 is covered by means of an Abdeok sleeve 62. It forms with the pot magnet 54 has a hollow _Λ space 63. The liquid flows duroh the mouth 65 of the conduit 52, at a mounted in the valve body 58 seal 66 by duroh the cavity 64 and an opening 67 in the pot 54 into the cavity 63. This leaves it through an opening 68 in the Abdeokbüchse 62. The magnetic field lines run here via the pot 54 into the cover plate 53, from this via an air gap into the valve body 58 and back into the sleeve 57 formed by the central part of the pot 54. The force characteristic is the same like that according to FIGS. 5 and 6. ^

In order to allow liquid to flow in between the (^ baffles of the valve body 58 and the sleeve 57 are on the end faces between the moving parts 58, 59 and the sleeve 57 as well the sleeve 71 diaphragms 69 and 70 attached, which the mentioned sliding surfaces and the opening 61 in which the bolt 59 slides against Close the cavities 63/64 filled with liquid. Choosing the spring steepness of the spring in the different versions so that, together with the magnetic force, there is no constant

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running resultant R over the valve lift ^ L results, so is it is possible to have the valve with a so-called negative characteristic equip. The differential pressure Δ ρ would increase with increasing Inflow volume or inflow velocity, according to the characteristic, sink. In the various versions in front of the overflow point, the cross-section through the position of the valve body is regulated, arranged orifice or nozzle 27 is designed as an inflow resistor. It serves to stabilize the flow.

It is also possible to use a valve body made of non-magnetic material to use, e.g. a self-supporting or on a thin coil support, which is located in the ring-shaped air gap a pot magnet can move, as is the case, for example, with moving coils of loudspeakers. Instead of a current-excited Magnets, a combination of a permanent magnet and a current-excited magnet can be used. The nib can be folded into In this case, as a result of the pretensioning it requires, caused by the permanent magnet, dimension it significantly better.

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Claims (5)

Patent claims 1. Controllable pressure control valve designed as an overflow valve to keep constant a continuously controllable pressure in a system, especially in a liquid system, with at least one, outflow nozzle acted upon during operation with controlled static medium pressure and one designed as an overflow point Valve passage for discharging the excess medium, characterized in that one or more electro-magnets and one or more g several springs are arranged in the valve in order to exert a position-independent force on the valve body in accordance with the coil current. 2. Pressure holding valve according to claim 1, characterized in that for the purpose of stabilization, in particular in the case of a negative characteristic, in which the system pressure decreases with increasing inflow, a flow resistance, for example a diaphragm (27), is arranged in front of the overflow point. 3. Pressure holding valve according to claim 1, characterized in that the magnet is designed as a combined permanent magnet and electromagnet is. 4. Pressure holding valve according to claim 3, characterized in that the magnet is designed as a pot magnet with the core of the pot as a sleeve is, in which a valve body designed as a piston is slidably arranged (Fig. 9). - 11 - 209817/0687 5. Pressure holding valve according to Anepruoh 4, characterized in that Seals are provided to keep τοη fluid flowing in to prevent the sleeve formed by the pot (Fig. 9}. - 12 - 209817/0687